Calculating apparatus



June 30, 1936. A. F. sPlTzGLAss ET A1.

CALCULAT ING APPARATUS Filed'Aug.

28, 1935 4 Sheets-Sheet 1 June 30, 1936. A. F. sPlTzGLAss ET AL.

CALCULATING PPARATUS 4 sheets-sheet 2 Filed Aug.l 28, 1933 June 30, 1936. Y' A. F. sPlTzGLAss ET A1. '2,045,621

CALCULATING APPARATUS Filed Aug. 28, 1953 4 Sheet,s-Sheell 3 June 30, 1936. A. F. sPlTzGLAsS ET Al.

CALCULATING APPARATUS Filed Aug. 28, 1953 4Sheets-Shee't 4 l Patented June3ll, 1,936 Y n c UNITED STAT/Es `vPli'rrsl'w'r OFFICE cago, lll., assignors to Republic Flow Meters Company, Chicago, Ill., a corporation of Illinois f- Applcation Aflgust'28, 1933, Serial No. l687,064 1 6 claims. icl. zas-e1) This invention relates to mechanical calcularatus comprises two or more parts, for example tion, especially multiplication and division, angularly-movable arms pivoted in a'novel relawhereby two or more independent quantities are tionship explained below, movable proportionateeach proportioned to the movement of parts, such 1y to the quantities to be multiplied, and arranged 5 for example as ar or the like movable around to actuate an indicating or actuated part propor- 5 given centers andA generating angles each in protlonately to the product of those quantities. In portion to the numerical value of one of the varythe illustrated arrangement all of these parts ing quantities, while by means such as a system move over graduated scales so that the product of links the-angles of movement corresponding to may be read from' the position of the indicating the respective quantities a`re combined to produce part on its scale, but the mechanism is also suited 10 a new angle or other function, whose magnitudel for uses in which such scales are not required. is proportional to the product (or other function) We prefer to so arrange the apparatus that of the respective angles corresponding to the in-g each of the scales is graduated in a uniform mandependent quantities. ner from a zero position at one end to a position Multiplication devices and the like of various at the other end representing unity, or one hunl5 kinds as now current in the art practically all dred per cent. That is, the decimal point in the embody either theprinciples of logarithmic adillustrated scales is disregarded the same as on dition or of repeated addition. The former are an ordinary slide rule, and all numbers are reinconvenient for many uses inasmuch as they regarded as being represented by unity (one hunquire irregular scales, so thatfor example it is dred per cent) or a decimal fraction thereof. 20 -exceedingly difficult to use them in indicating and By this arrangement all products also fall between recording instruments and the like. 'I'hey are zero (0 x'0) and unity (1 x l), or (if regardedas also'limited -to the multiplication of two factors percentages) between 0% and 100%- f L at a time. That is, the multiplication of three or In one simple and effective arrangement, the

moreV quantities cannot conveniently be made invention is embodied in a simple linkage or the 25 simultaneously but is made as a series o'f sepalike, shown as including pivoted arms movable to rate operations involving only two factors ata. represent the quantities being multiplied betime. The mechanical devices operating on the tween zero positions and positions representing principle of repeated addition arel complicated unity (or one hundred. per cent). 'I'hese arms,

and expensive; and do not give simple directin the arrangement shown in the dawin'gsgare ,30

reading results which adapt them for. use as partsl mounted at opposite ends on. pivots whose axes 1 of various devices which require movements prorespectively substantially intersect the opposite portional to both of two quantities (and there'- arms when in the positions representing unity.' fore toltheir prqduct) From a slightly different point of view, the frame It is an bject of the present invention to en- J of the apparatus may be regarded as the equiva- 35 4able the simultaneous multiplication of more than y lent of a fixed link connecting the two pivots.

operation of multiplication (or division) of two links or the like to a part which is moved in` a or more quantities with scales having movesector-shapedarea inaccordance with the move- 40 ments/ with equal increments for -the same ment of both of the pivoted arms. 'I'he move- 40 chang-es in the quantities, and thereforesuitable ment of this part is transferred, by means such for use in various types ofv instruments. It is as anotherconnecting link, or by an equivalent moreover an important object to provide a simple, y geared arrangement, to a third pivotedarm formfool-proof, and inexpensive apparatus for multiing the indicating or actuated member, and 4 `plying (or dividing) two or more quantities in a. which preferably moves over a scale from which 45 certain and accurate manner. Another object is the product can be read,. or which is connected 4 to make the motion -of each element of the apto suitable indicating' or recording means in va.- paratus independent of the motion of all the, rious instruments in which the apparatus may other elements representing the quantities, so be used. A

"0 that mechanical means can be readily'utilized to In the arrangement which at present we con- -50 move or be moved by all the various elements sider the simplest, this last or actuated arm is simultaneously or at intervals to the proper. pomounted with its pivot coaxial with th pivot of sitions on the scales and to obtain their product one of the iirst two arms, and generally at a pre- (or quotient) on an equally dividednatural scale. determined angle such as a right angle to one '55 Having these objects in view, one form of appaofthe arms when both are in their 50% positions,- 5?

and with its scale having its zero coincident or in line with the zero of the scale of' the other of the first two arms, the two scales being therefore intersecting arcs in the arrangement illustrated.

Thus the actuated arm and its link, and the above-mentioned arm of the iirst two together with its link, form in this particular embodiment a parallelogram linkage, with the above-mentioned -part movable in Iits sector arranged to serve as the connection between the two links. This part is also connected by a link to the movable end of the other one of the i-lrst two arms, and is actuated thereby to swing the parallelograrn in such a manner as to transfer the desired product to the scale of the actuated arm.

The above operation can of course be reversed, in the case of dividing one quantity by another, the quotient being read on one of the first two arms, the actuated arm being set (either directly or by manipulating said one of the other arms) for one of the two quantities and the other of the rst two arms being set for the other (the divisor). It is the intention, throughout the description and claims, wherever multiplication is spoken of, to include division by this obvious reversal of the manner of reading.

The above described linkage may be compounded, as fully explained below, to include further elements operating on the same principles and giving the product (or quotient) o three or more quantities. Further, by suitable manipulation hereinafter described, the powers and roots of numbers may be obtained, this being a special case of multiplication or division where two or more of the quantities are the same.

Another feature of the invention relates to connecting the arms or their equivalents by gearing ork the like, so that they move together to extract roots and raise to powers directly. Preferably the connecting means is disconnectable so that the apparatus may also be used for ordinary multiplication and division as described above.

rlhe above and other objects and features of the invention, including various novel combinations of parts and desirable particular constructions, will be apparent from the following description of the illustrative embodiment shown in the accompanying drawings, in which:

Figure l is a perspective view` of the illustrative form of apparatus, with the parts in the positions they would occupy in multiplying .6 by .4 (or, in percentages, 60% by 40%), or in dividing .24 by either .6 or .4 in reading backwards to divide instead of multiply;

Figure 2 is a diagram, on a larger scale, of the sector-shaped area traversed by the part which connects the links from the first and third arms and which is connected by another link to the movable end of the second arm;

Figures 3, 4, 5, and 6 are diagrammatic views of the apparatus of Figure 1, with the parts in different positions;

Figure '7 is a perspective view of a modification for multiplying (or dividing) three quantities;

Figures 8 and 9 are diagrams used in one explanation of the operationof the apparatus;

Figure l0 is a view corresponding to Figure 7, but showing disconnectable gearing for causing the parts to move together to extract roots andl raise topowers;

Figure 1l is a plan view nism of Figure '10; and

diagram of the mecha- `pointer 22 Figures l2, 13, and 14 are views, in three diiferent positions, of a lever-and-gear arrangement which can be substituted for the actuated arm and its link in Figure 1.

The apparatus in the particular embodiment shown in Figure 1, regarded as a. mechanical structure, includes an arm i0 having a pointer i2 at its upper end and mounted at i4 at its lower end on a pivot or shaft for angular movement to carry the pointer i2 between a zero position at the left end of a scale i6 and a position at the right end of the scale representing or unity.

Mounted on a pivot orvk shaft it, which is in line with the arm il) adjacent its movable end at the time pointer i2 is at its 100% (or unity) position on scale it, is a second arm 20 having a at its lower end. The pivots or shafts M and i8 are shown mounted in suitable stationary brackets or other supports 24 and 26. i

The pivots i4 and i8 may be regarded as connected by a rigid link or other connection, which in this case is the frame of the apparatus.

The pointer 22 swings along a scale 28 having its zero position at the right in such a position that the arm 20 at zero is parallel to the arm [I0 at zero, and having its 100% (or unity) position at the left.

It will be seen that 28 in line with the axis of the shaft or pivot i4, or at least on a line intersecting this axis and drawn from the axis oi the shaft or pivot i8. Actually, of course, the scale 28 may be moved up or down and at the same time made shorter or longer, so long as the zero represents the position of arm 20 when parallel to arm l0 inI its zero position and the 100 represents the position of arm 2l) when it lies along a line connecting the two shafts or pivots it and it.

The third or indicator arm, indicated at 30, is mounted horizontally (i. e. generally perpendicuthis brings the 100 on scale n lar to the arm l0) on a shaftl or pivot 32 which is coaxial with respect to the shaft or pivot i4 and which is shown mounted on an arm '34 of the bracket or support 2a. Arms i0 and 30, in this embodiment, are only exactly perpendicular when both are in their 50% positions.

The indicator arm 30 has a pointer 36 moving over a vertical scale 30. The zero of the scale 30 is determined by the position of the arm 30 when both arm l0 and arm 20 are in their zero positions. The 100% (or unity) position of the scale 38 is determined by the position of the arm 30 when the arms i0 and 20 are in their 100%. (or unity) positions. In the arrangement illustrated, the scale 38, like the scale it-y and the scale 28, is an arc of 30.

The first arm i0 and the third arm 30 are connected by two links i0 and 42. The link 40 is connected to arm i0 at the intersection of that to arm 30 at such a point that arms l0 and 30 l and links 40 and 42 form a true parallelogram.

The two links 4I) and 42 are connected by a part such as a floating -shaft or pivot 46, to which is also connected a third link 40, equal in length to link 42. The lower end of the link 40 is pivot- 75 v lar movements of link 48 I0-40-4230, to each other,'one behind the other; pointer 50 ally connected to the lower end of the arm 20. The upper ends of links' 42 and 48 at all times move about the same floating shaft or pivot 46); their pivots at their lower ends are coaxial so long as both arms 20 and 30 are in zero position.

For convenience" in the following description, although not necessary to the manipulation of regardless of the anguabout that axis.

' The pointer 50, to facilitate the description of the operation of' the apparatus, is shown movable over a sector-shaped diagram 52, shown on an enlarged scale in Figure 2. This diagram is conby similarly moving arm arm Il) at each 10 points It will vbe seen that the in this embodiment have in general, four limiting positions shown' respectively in Figures, 4, 5, and 6.

on its scale.

axis of the pivotconis coincident with the I8 on which the arm 20 20 are coincident, and the necting links 40 and 42 axis of the shaft or pivot is mounted.

Now if arm I 0 is moved to bring pointer I2 to I6, we have the parts in the po- The arm 20 may now be moved to carry its pointer 22 to 100 on its scale 28, giving the arrangement shown in Figure 5. The link48 is now the diagonal of parallelogram I 0-.40 42-30; arm I0 and link 20 are now parallel, one behind the other; pointer 50 has moved'to the lower righthand corner of its sector-shaped diagram 52; and pointer 36 of arm 30 Has moved to 100 on its scale 38.

and 100 onthe scale 28.

Arm I0 may now be moved to carry its pointer I2 back and they are arranged parallel has moved backto its starting point at the apex of its sector-shaped diagram 52 and pointer 36 has moved back to zero. 'Ihis obviously is corpointer 36 now indicates the product of 0 on scale I6 and 100 on scale 28.

Moving arm 28 to carry its pointer 22 back to zero on its scale 28 would put the parts back in the positions shown in Figure 3.

It willy be'seen, by a comparison of the abovedescribed four gures, that so long as, pointer I2 axis (i. e. the axis of theJ 2o from o to 10o wmf is set at 0, no movement ot arm 28 will move pointer 36 away from 0 on its scale 38as arm 20 and link 48 merely swing idly about their coincident axes Aat theirupper ends. Similarly, so long as the pointer 22 is at 0, the parallelogram I0404230 merely swings idly between the and ,48 remain parallel, one behind the other, and

merely swing idly back and i'orth. r

Figures 1 and 2 illustrate the multiplication of numbers where both the pointers I2 and 22 are in intermediate positions between Oand 100 on their respective scales.. I2 is at 60 andthe pointer 221s at 40, thereby moving pointer 50 to the intersection oi' the horizontal "40 arc with the vertical 60" and 40, and and 30). f

Similarly each position of the pointer 36 on its scale represents a curve Thus by setting pointer I2 for one quantity, and the other quantity, the product of any two quantities will be shown by pointer 36 on its scale 38.

It is believed tion that, in the case of division, thedividend may be set on the scale 38 and the divisor on either`the scale 28 or the scale I6, whereupon then move the arm I0 (or 20) until pointer 36 ls opposite the dividend on scale 38 (instead of directly manipulatingthe arm 30 to move pointer 36 to that position), whereupon it will be found that pointer I2 (or 22) shows the quotient on its scale VI (or 28) In the claims, especially, rwhere multiplication is spoken of it is intendedthat the terms used be construed broadly toinclude thisk Empirically, shown that ordinarily used by disregarding decimal points, the same as In Figure l the pointer 35' obvious without further descrip- 4 decimal point. Similar types of graduation for other special purposes will. be readily apparent.

Securing the square of a quantity merely means setting the quantity on both of the scales I6 and 28. The instrument could be modified for this purpose, Vif desired, by gearing the arms I0 and 20 together or otherwise connecting them so that they will move through equal arcs `(preferably by gearing or other means which can be disc0n nected to permit ordinary multiplication). In this case the setting of the quantity to be squared on the scale I6 (or 28) would automatically give its square on the scale 38. In this case, also, square roots could be obtained, since the setting of any quantity on the scale 38 would automatically show the square root on the scale I6 (or 28). Such obtaining of squares, and square roots,l are special cases of multiplication and division respectively, and are intended to be included in the scope of my claims.

In the illustrated apparatus, each of the scales I6, 28, and 38 is 30 of arc about its center.

In Figure '1 the apparatus is compounded to give the product (or quotient) of three quantities. The part of the instrument for multiplying the first two quantities is the same as previously de# scribed, except that for convenience of manipulation the arm |30 is made somewhat longer than the arm 30, so thatits scale |38 (while of the same length as scale 38 in v4degrees) is linearly somewhat longer.

In the compounded part of the apparatus, arm |30 is connected up and has the'functions of the arm |0 in the multiplication of the first two quantities. That is, the product (as indicated by pointer |36 on scale |38 kand determined by the position of arm |30) of the first two quantities, and the third quantity, are to be regarded as two more quantities to be multiplied.

The third quantity (illustrated as being the number 30) is set by means of a pointer |22 movable over a scale 68 shown graduated from 0 to 100. The pointer |22 is mounted on a fourth larm |20 horizontally mounted on a--shaft or pivot I I8 vcarried by a bracket or support |26 arranged near the 100 end of scale |38.

The movable end of the arm |20 is connected by a link |48 to a iioating shaft or pivot |46. The link |48 may if desired have a pointer |50 in the axis of the shaft orpivot |46 and movable over a sector-shaped diagram |52 corresponding to the diagram 52.

The floating shaft or pivot |46 is coaxial with respect to the shaftor pivot I8 when the pointer |50 is at the apex of its sector, this being at the time the arm |30 is at zero, and forms the conand 32.

nection between two links |40 and |42 forming two sides of a secondary parallelogram. Link |42 is equal in length to that part of arm |30 between the axis of its pivot and itspoint of pivotal connection to the upper end of link |40. Link |40 is equal in length to the effective length of a fifth', or secondary indicator, arm 230 extending downwardly from a shaft or pivot 232 on the bracket 34 and coaxial'with respect to pivots |4 Arm 230 forms the fourth side .of the secondary parallelogram.

Arm 230 is provided at its end with a pointer 236 moving along a. iinal scale 238 on which the product of the three quantities is shown. To distinguish it conveniently, in use, from scale |38 the scale 238 lis shown graduated from 0 to 1000. In the drawings, the three quantities 60, 70, and 30 are being multiplied to give 126,000. Disregarding the decimal point, this shows as 126 on the scale 238.

` If the quantities are to be read (decimal points and all) on the scales, just as scale |38 would have to be graduated from 0 to 10,000, so would scale 238 have to be graduated from 0 to 1,000,000.l

The modification shown in Figure '7 of course also can be operated in reverse order to divide instead of multiply. Also, by gearing or otherwise connecting arm |20 to the arms I0 and 20, so that they all three move angularly in unison, it can be used to secure the cube or the cube root of a quantity.

Figure 8 is a diagram which may be used in explaining one theory of operation. In this dagram, 80 is a rigid link connecting the iixed centers I4 and I8, or an equivalent connecting means such as the instrument casing in which the pivots I4 and I8 are mounted. The reference character 82 indicates a line from the pivotal connection off arm |0 and link 40, to the uppermost end-of the vertical arc in sector 52 on which the pointer 50 rests. It will be noted that in any position of the arm I0, the line 82 is parallel to the origirzl position of link 40 when arm I0 is at zero. The other reference characters indicate the same parts as in Figure l, in their zero positions, primes and seconds being used to indicate the same parts in other than zero positions.

It will be seen that the angle between arm I0 and line 80 is indicated as the angle a. In the illustration, angle a is 30. When arm I0 is moved to. a new position I0', it moves through an angle Aa, corresponding to one of the quantities to be multiplied, and which decreases the original angle a by that much.

The angle between arm 20 and line 80 is indicated as and in the illustration is also 30. The angle through which arm'20 is moved to a new position 20 is indicated as A13, and corresponds to thesecond of the two quantities to be multiplied.

The original position of the link 40 relatively to the fixed reference line 80 is indicated by the angle a. Moving arm I0 to position I0', and moving arm 20 to position 20', shifts link 40 to a positionl, the angular movement of the link (which corresponds to the product of the two quantities) being the angle Aa. Since line 82 is parallel to the original or zero position of link 40, it will be seen that the angle between this line 82 and the link in its position 40 will also be angle Aa.

Since. the angle Aa is proportionate, to the required product, the arcuate distance from line 82 to pointer 50 is of course also proportionate to that product. This is the distance which is transferred to the indicating arm 30 by means such as the link- 42 or its equivalent, and is finally indicated on the scale 3 8.

From the point of View of this explanation, it will be seen that the principal parts of the apparatus comprise a link or casing or other support 80 iixing the relative positions4 of two pivots I4 and I8, two levers mountedon said pivots and preferably parallel to each other in their zero positions, and two ylinks (40 and 48) connected to each other and to the movable ends of the levers.

For the sake of clearness, the initial positions of the parts, with arm 30 and link 42 added, are shown separately in Figure 9.

In Figure 10 is shown one arrangement for connecting the levers I0, 20, |20, etc., for extracting roots and raising to powers. In thisarrangement. arm I0 is provided with a'n arcuate rack 3|0, arm 20 has a similar arcuate rack 320, and arm |20 has a. similar arcuate rack 420. These three racks all stituted for the link 42 shown) so that it may be shifted axially to the left to disengage pinion 84, from the three racks, so that the device may be used for ordinary multiplication and division.

In Figure 11 is shown a diagram of the mechaof Figure 10, with the levers I0, 20, and |20, and their three 'racks 3|0, 320, and 420, together with the segmental pinion 84. shown in plan, and the other parts indicated diagrammatically by lines. l

t In Figures 12, 13, and 14 there is shown, in three positions, a gear mechanism which may be suband the arm 30. 'I'his mechanism is mounted on, and carried by, the arm l0. y

In the illustrated form,

lower arm of bellcrank 540, and carries an arcuate rack 90. The racks 88 and 90 both mesh with a pinion 542 journaled on the arm l0, so that they must always move oppo- `sitely and in equal amounts. Thus the angular motions of bellcrank 540 as is the case with a parallelogram linkage. As shown in dotted lines in Figure 14, the pointer 63,6 .and its pointer arm maybe desirable or convenient to have it. i' While several particular illustrative embodion the instrument that it second link being equal in length to said first, second and third arms.F

2. An` instrument ed on a fixed pivot coaxial with the piv'ot of said rst arm, and a `second link pivoted to the third arm being of equal length and the second link and rst, second and length.

3. An instrument comprising a pair of arms pivoted at one end on coaxial fixed pivots, a third arm pivoted at one end on a xed pivot spaced from the first pivot,I and three links coaxially pivoted at one end on a. iloating pivot and having their free ends pivotally connected to the free ends of said arms respectively.

4. An instrument comprising four links pivotall`y connected at their ends to form a parallelogram linkage, one of the pivot points being xed, a, fth link connected to the pivot point diametrically opposite to the fixed pivot, and a sixth link pivoted at one end to the free end of the fth link and at its other end to a fixed pivot spaced from the first ilxed pivot.

5. An instrument comprising four links pivotally interconnected at their ends, alternate ones of said links being of equal length to form a parallelogram linkage and one of the pivots being xed, a fth link connected to the pivot diametrically opposite the xed pivot and equal in length to one of the adjacent link equal in length to the fth link and pivoted to the free end of the lfth link at one of its ends, the other end oi the sixth link being connected to a A the ilrst xed pivot a distance equal to the lengthof the sixth links, and a sixth mounted on said pivot, a second pivot spaced from said first pivot a distance equal to the length of said arm, a second arm mounted on said second pivot and equal in length to said first ariri, a third arm equal in length to said first and second arms and pivoted at one end on the free end of the second arm, and a link connecting the free ends of the first and third arms.

8. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from,y

said first pivot a distance equal to the length of said arm, a second arm mounted on said second pivot and equal in length to said first arm, a third arm equal in length to said first and second arms and pivoted at one end on the free end of the second arm, and a link connecting the free ends of the first and third arms, a fourth arm pivoted coaxially with said first pivot, and means connecting said link and said fourth arm to move the fourth arm angularly proportionately to angular movement of the link.

9. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spacedfrom said rst pivot a distance equal to the length of said arm, a second arm mounted on said second pivot and equal in length to said first arm, a third arm equal in length to said first and .second arms and pivoted at one end on the free end of the second arm, and a link connect-v ing the free ends of the first and third arms, a fourth arm pivoted coaxially with said first pivot, and gearing carried by said first arm and connecting said link and said fourth arm to move the fourth arm angularly proportionately to angular movements of the link.

10. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from said first pivot a distanceequal to the length of said arm, a second arm mounted on said second pivot and equal in length to said first arm, a third arm equal in length to said first and second arms and pivoted at one end on the free end of the second arm, and a link connecting the free ends of the first and third arms, a fourth arm pivoted coaxially with said first pivot, gear seg- .ments carried by said fourh arm and said link,

and a gear carried by said first arm and meshing with said segments to maintain the fourth arm and the link in parallelism.

l1. An instrument comprising a pivot, an arm `mounted on said pivot, a second pivot spaced from said first pivot a distance equal to the length of said arm, a second arm mounted on said second pivot and equal in length to said first arm, a third arm equal in length to said first and second arms and pivoted at one end on the free end of the second arm, and a link connecting the free ends of the first and third arms, a fourth arm vpivoted coaxially with said first pivot, and a second link connecting said first link and said fourth arm to move the fourth arm angularly proporaccesar 12. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from said first pivot a distance equal to the length of said arm, a second arm mounted on said second pivot and equal in length to said first arm, a third arm equal in length to said first and second arms and pivoted at one end on the free end of the second arm, and a link connecting the free ends of the first and third arms, a fourth arm equal in length to said link pivoted coaxially with said first pivot, and a second link equal in length to said iirst three arms connecting the first link vand fourth arm to maintain the same in parallelism.

13. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from the first pivot a distance equal to the length of the arm, a second arm equal inlength to the first arm and mounted on the second pivot, a third arm equal in length to the rst and second arms and pivoted to the free end of the second arm, a link connecting the free ends of the first and third arms, and means connecting the iirst and second arms for simultaneo 1y moving them through equal angles. 4

14. A instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from the first pivot a distance equal to the length of the arm, a second arm equal in length to the first arm and mounted on the second pivot, a

third arm equal vin length to the iirst and second arms and pivoted to the free end of the second arm, a link connecting the free ends of the first and third arms, a fourth arm pivoted coaxially with said first arm, means connecting said fourth arm to said link to move the fourth arm angularly proportionately to angular movements of the link, a third pivot spaced from said first pivot a distance equal to the length of the fourth arm, a

fifth arm equal in length to the fourth arm and pivoted on said third pivot, a' sixth arm equal in length to said fourth arm and pivoted to the free end of the fifth arm, and a link connecting the free ends of the fourth and sixth arms.

15. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from the first pivot-a distance equal to the length of the arm, a second arm equal in length to the first arm and mounted on the second pivot, a-

third arm equal -in length to the first and second arms and pivoted to the free end of the second arm, a link connecting the free ends of the first and third arms, a fourth arm pivoted coaxially with said first arm, means connecting said fourth arm to said link to move the fourth arm angularly proportionately to angular movements of the link, a third pivot spaced from said iirst pivot a distance equal to the length of the fourth arm, a fifth arm equal in length to the fourth arm and pivoted on said third pivot, a sixth arm equal in length to said fourth arm and pivoted to the free end of the fifth arm, a link connecting the free ends of the fourth and sixth arms, a seventh arm pivoted coaxially with said 'first pivot, and means connecting the seventh arm and the last named link to move the seventh arm angularly proportionately to angular movement of the said link.

16. An instrument comprising a pivot, an arm mounted on said pivot, a second pivot spaced from the first pivot a distance equal to the length of the arm, a' second arm equal in length to the first arm equal in length to the first and second arms 75 tionately to angular movements of the first link. and pivoted to the free end of the second arm, a 75 link connecting the free ends of the rst and third arms, a fourth arm pivoted coaxially with said first arm, means connecting said fourth arm to said link to move the fourth arm angularly proportionately to angular movements of the link, a third pivot spaced from said irst pivot a. distance equal to the length of the fourth arm, a fifth arm equal in length to the fourth arm and pivoted on said third pivot, a sixth arm equal 1n length to' said fourth arm and pivoted to the free end of the fifth arm, a link connecting the free ends of the fourth and'sixth arms, and means for simultaneously moving the first, second, and fifth arms through equal angles whereby the last vnamed link will be moved through an angle proportionate to the cube of the angular movement of said arms.

ALBERT F. SPITZGLASS. OTTO T. HANDWERK.

Certificate of Correction Patent No. 2,045,621. June 3o, 1936.

ALBERT F. SPITZGLASS ETAL. certified that errors appear in the printedv specification oi the above It is hereby numbered patent equirmg correction as follows: Page .4, second column, hnes 44, 48,-

v 51, and 52, `stl'iljre out the Greek letter alpha ,d and Insert instead the Greek letter gamma 7; and that the said Letters Patent should be read with these corrections therein that the same may conform to the record of the'case in the Patent OIice.

Signed and sealed this 18th day of August, A. D. 1936.

[SEAL] HENRY VAN ARSDALE,

Acting Commissioner of Patents.

Certificate of Correction Patent No. 2,045,621. June 30, 1936.

ALBERT vF. SPITZGLASS ET AL.

It is hereby certified that errors appear in the printed specification of the above numbered patent requiring correction as follows: Page 4, second column, lines 44, 48,

51, and 52, vstrike out the Greek letter alpha, d and insert instead the Greek letter gamma 'y; and that the said Letters Patent should be read with these corrections therein that the same may conform to the record of the'case in the Patent Office.

Signed and sealed this 18th day of August, A. D. 1936.

[SEAL] HENRY VAN ARSDALE;

Acting Commissioner Qf Patents. 

